Research Article
Acmella oleracea and Achyrocline satureioides as Sources of
Natural Products in Topical Wound Care

Lais Thiemi Yamane,1 Eneida de Paula,2 Michelle Pedroza Jorge,1

Verônica Santana de Freitas-Blanco,1 Ílio Montanari Junior,1

Glyn Mara Figueira,1 Luís Adriano Anholeto,3 Patricia Rosa de Oliveira,3

and Rodney Alexandre Ferreira Rodrigues1

1Chemical, Biological and Agricultural Research Center (CPQBA), University of Campinas, Campinas, SP, Brazil
2Biology Institute, Department of Biochemistry and Tissue Biology, University of Campinas, Campinas, SP, Brazil
3Institute of Biosciences, Department of Biology, Sao Paulo State University, Rio Claro, SP, Brazil

Correspondence should be addressed to Rodney Alexandre Ferreira Rodrigues; rodney@cpqba.unicamp.br

Received 26 February 2016; Revised 18 May 2016; Accepted 29 August 2016

Academic Editor: Nativ Dudai

Copyright © 2016 Lais Thiemi Yamane et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

The Brazilian forests have one of the world’s biggest biodiversities. Achyrocline satureioides (macela) and Acmella oleracea (jambu)
are native species from Brazil with a huge therapeutic potential, with proved anti-inflammatory and anesthetic action, respectively.
The jambu’s crude extract after depigmentation with activated charcoal and macela’s essential oil were incorporated in a film
made with hydroxyethyl cellulose. Those films were evaluated by mechanical test using a texturometer and anti-inflammatory
and anesthetic activities by in vivo tests: wound healing and antinociceptive. The film containing the highest concentration of
depigmented jambu’s extract and macela’s essential oil obtained an anesthesia time of 83.6 (±28.5)min longer when compared with
the positive control EMLA�; the same occurred with the wound healing test; the film containing the highest concentration had a
higherwound contraction (62.0%±12.1) compared to the positive control allantoin and the histopathological analysis demonstrated
that it increases collagen synthesis and epidermal thickening. The results demonstrate that the films have a potential use in skin
wounds, pressure sore, and infected surgical wounds treatment.

1. Introduction

The wound dressing market has grown significantly over
last 10 years; however fewer dressings have all the required
properties for the purpose of wound protection and healing.
Natural polymers are of special interest due to low toxicity,
high absorption, and swelling capacities; moreover, various
active compounds can be incorporated into these polymers
[1].

The hydroxyethyl cellulose (HEC) is considered the most
abundant natural polymer, renewable, soluble in water, with
low toxicity, film-forming, with good stability from pH 2 and
pH 12, is relatively inexpensive, and is widely used in various
types of dressings to have hemostatic property [2–4]. The
prevalence of chronic wounds in the general population is

relatively high; improving wound healing, severe burns, and
postoperative remains a challenge due to the high cost of
existing therapies [5]. The use of opioids is widely used as
anesthetics for postoperative and deep wounds, but there are
disadvantages as possible side effects (respiratory depression,
nausea, vomiting, constipation, and urinary retention) [6]
and antibiotics are generally used to prevent and treat
infections; nonetheless their activity is gradually diminishing
due to the rise of resistance to these drugs [1].

Topical formulations are noninvasive and with few side
effects; a good example is patches, a topical adhesive that have
constant and prolonged release, avoiding peak plasma levels,
andmay reduce the duration of pain [7].The patch with plant
extracts has been used to reduce inflammation and aid in
healing [5].

Hindawi Publishing Corporation
Evidence-Based Complementary and Alternative Medicine
Volume 2016, Article ID 3606820, 9 pages
http://dx.doi.org/10.1155/2016/3606820



2 Evidence-Based Complementary and Alternative Medicine

Brazilian biome contains more than 20% of the biodiver-
sity of world [8], with a wide variety of available molecules
for human therapy in pharmaceutical, food, cosmetic, and
veterinary fields [9]. Two species that are used in popular
culture and native of Brazil and South America were used for
this study, Achyrocline satureioides Lam. (DC) (Asteraceae)
known as macela or marcela, used in folk medicine as
an analgesic, sedative, and abdominal cramping. There is
scientific evidence of anti-inflammatory, antispasmodic, and
antioxidant action [10]. The essential oil compounds have
been identified as 𝛼-pinene, copaene, and the isomers 𝛽-
caryophyllene and 𝛼-caryophyllene (or 𝛼-humulene); the
last two are the major compounds present in essential oil
of plants in Brazil [11]. Its main component of interest is
the 𝛼-humulene, responsible for anti-inflammatory activity
[12]. Acmella oleracea (L.) RK Jansen (Asteraceae), popularly
known in Brazil as jambu, is widely used in cooking and
also popularly used to treat toothaches, tuberculosis, and
anemia and as appetite stimulant [13]; these activities are
attributed to bioactive compounds, coumarins (scopoletin),
triterpenoids, essential oils (limonene and 𝛽-caryophyllene)
amino acids, phytosterols, phenolic compounds (vanillic
acid, trans-ferulic acid, and trans-isoferulic acid), and N-
alkylamides; its main component is spilanthol responsible for
anesthetic activity [14–17].

The use of an anesthetic and anti-inflammatory is impor-
tant to reduce pain and have good wound healing, for
reducing the risk of infection and further complications. It is
also reported that inflammatory mediators such as histamine
and prostaglandin E2 may be related to the inhibition of
collagen synthesis and fibroblast proliferation, important
components for wound healing [18, 19].

The aim of this work was to develop and to evaluate
an anesthetic and anti-inflammatory bioadhesive film con-
taining jambu extract and macela essential oil, by studying
its mechanical properties, in vitro skin permeation char-
acteristics, and in vivo performance, in comparison with
commercial formulations.

2. Materials and Methods

2.1. Chemicals. HEC and 𝛼-humulene standard (96% purity)
were purchased from Sigma-Aldrich Co., Saint Louis, USA.
Spilanthol standard (88.5%) purity was purchased from
Chromadex, California, USA. Glycerin was purchased from
Vetec Quı́mica Fina, Rio de Janeiro, Brazil. Transcutol�
(ethoxydiglycol) was purchased from Gattefossé�, Lyon,
France. Activated carbon was purchased from Carbomafra�,
Curitiba, Brazil. Diatomaceous Earth and Tween 80� were
purchased from Synth, São Paulo, Brazil. Allantoin was
purchased from Fagron, Hong Kong, China.

All other reagents were of analytical grade.

2.2. Plant Material. The plant material was sown and
grown in the experimental field of the Multidisciplinary
Center for Chemical, Biological and Agricultural Research
(CPQBA)/UNICAMP, located in the city of Paulinia, Brazil.
This project was authorized by the Council of the Genetic
Heritage Management, under protocol number 01232/2014-1.

2.3. Production of JambuEthanolic Extract andTreatmentwith
Activated Charcoal. Jambu aerial parts were collected, dried,
milled, and extracted 3 times with 96∘ GL ethanol (1 : 5 w/v)
for 1.5 h. The three fractions were pooled and filtered in
Buchner funnel with filter paper under vacuum. Then the
crude extract was weighed and treated with 4% of activated
charcoal; the mixture crude extract and activated charcoal
were placed in a warm bath at 40∘C with constant stirring for
one hour. The extract was filtered with diatomaceous earth
(Celite�) and evaporated at 40∘C under reduced pressure
(model R-215, Büchi) and then lyophilized until constant
weight. Solvent-free extract was stored in a freezer until use.

2.4. Macela Volatile Oil Production. The volatile oil was
obtained from fresh inflorescences in Clevenger apparatus by
hydrodistillation held for a period of 2 h according González
and Marioli [20]. The oil was separated from the water in a
separation funnel and anhydrous sodium sulfatewas added to
remove residualwater.Theoil was stored in a freezer until use.

2.5. GC-MSAnalysis. The analytical monitoring of spilanthol
and 𝛼-humulene in the extract, essential oil, and films
was performed by gas chromatograph coupled with a mass
detector (CG-EM, Hewlett Packard 5890, series II, mass
selective detector 5970 EI 70 eV) equipped with a fused silica
column WCOT, HP5-MS, Agilent�, with 30m × 0.25mm ×
0.25 𝜇mof dimension.The analysis conditions were injection
temperature: 220∘C, detector temperature: 250∘C, and tem-
perature program: 60–240∘C (3∘C/min). The identification
and quantification of spilanthol and 𝛼-humulene were made
by the external standard method with commercial analytical
standard [21].

2.6. Preparation and Characterization of HEC Films. To
produce the films, 2.5% of HEC was added in 100mL ultra-
pure water and the resulting mixture kept under magnetic
stirring and heating at 55∘C until complete dissolution. The
mixture rested until it reaches room temperature and then
jambu depigmented crude extract (10.0 and 15.0%), macela’s
essential oil (1.0 and 1.5%), 5.0% of Transcutol, 0,7% of Tween
80, and 0.7% of glycerin were added. The homogeneous
solution was transferred to Nylon plates, which were dried
in an oven at 40∘C for 24 h.

After drying, the films were removed from the plates and
cut with a punch with 17mm in diameter, size compatible
with the wound healing test and antinociceptive activity tests.
Thefilmswereweighed on an analytical scale (Mettler Toledo,
São Paulo, Brazil) and their thickness was measured with a
digital caliper (model Cal II, Tesa, Renens, Switzerland).

2.7. Mechanical Resistance Properties. Mechanical properties
of the films with extract and essential oil and placebo film
(HEC, Transcutol, Tween 80, and glycerin) were evaluated
using a texturometer from Stabile Micro Systems (model
TA-TX Enhanced, Godalming, United Kingdom) evaluating
resistance to perforation, relaxation, and resilience. The
determination parameters were set as distance of 30mm for
the perforation resistance tests, distance of 2mm for both



Evidence-Based Complementary and Alternative Medicine 3

resilience and relaxation tests, and a force of 5 g for all tests.
All determinations were performed in triplicate [22].

2.8. Pharmacological Tests

2.8.1. Animals. Male Wistar rats (250–300 g) and male Swiss
mice (25–40 g) were obtained from CEMIB-UNICAMP
(Multidisciplinary Center for Biological Research, State Uni-
versity of Campinas, UNICAMP, Campinas, São Paulo,
Brazil). All animals were housed in polycarbonate cages,
under a climate-controlled environment (22 ± 3∘C and
relative humidity 30–70%), a light/dark 12 h cycle, and feed
ad libitum with convectional standard palletized laboratory
ration (Nuvilab�) and water. Protocols were approved by the
UNICAMP Institutional Animal Care and Use Committee,
which follows the recommendations of theGuide for theCare
and use of Laboratory Animals (CEUA number 3342-1).

2.8.2. Evaluation of Wound Healing Activity in Rats. This
assay was performed according to Jorge et al. [23].Wistar rats
were divided in 6 groups of 5 animals each: group I, saline
0.9% (0.5mL/animal, negative control); group II, allantoin
(100mg/animal, positive control); group III, FI: film with
10.0% of depigmented jambu’s extract with 1% of macela’s
essential oil (250mg/animal); group IV, FII: film with 15.0%
of depigmented jambu’s extract with 1,5% ofmacela’s essential
oil (250mg/animal); group V, FIII: placebo film. Cutaneous
ulcers were visually examined daily; also photos were taken
and the percentage of reduction of the initial lesion area were
calculated, by ImageJ� program.

At the end of the experiment the animals were sacrificed
by deepening anesthesia (thiopental) and skin samples were
removed (epidermis, dermis and hypodermis) of the same
treatment site. These were removed from groups 4, allantoin,
FI, FII, and FIII, placed in 10% formalin solution and stained
with Trichrome Masson and Hematoxylin/Eosin. By storage
issues the saline group was lost. The stained slides were
examined by light microscopy.

2.8.3. Tail-Flick Test in Mice. This assay was performed
according to de Araujo et al. [24], with some modifications,
such as cut-off time, intervals measurement, and animal
employed. The animals were placed in a horizontal acrylic
restraint with the distal portion of the tail free and exposed
to heat from a lamp (55 ± 1∘C). The timer stopped when the
exposed rat tail flicks, and the interval between switching on
the light and flick of the tail was recorded (latency time).
A 10 s cut-off time was used to avoid thermal injury, and
the baseline (normal response to the noxious stimulus) was
recorded before starting the experiments. The animals were
divided into 4 groups: group I, FI; group II, FII; group III,
FIII; and group IV, EMLA 150mg/animal (positive control).
The films and EMLA were applied to 2 cm from the base
of the animal’s tail for 5min; after its removal, the tail was
exposed to light focused on the same region where the film
was applied and the test was started after the tail removal.
The measurements were made every 15min until the animal
returned to its baseline response to noxious stimuli.

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Figure 1: GC-MS chromatogram of commercial analytical standard
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2.9. Statistical Analysis. Characterization and in vivo phar-
macological data were expressed as percentage or mean ±
SD and analyzed by one-way analysis of variance (one-way
ANOVA) with Tukey-Kramer post hoc tests using Graph Pad
Instat (Graph Pad Software Inc., USA).

3. Results

3.1. Yield from Extraction Processes and GC-MS Analysis. The
average yield of depigmented jambu crude extract on a dry
basis was 3.7% and average yield of macela’s essential oil was
0.04%.

The chromatograms obtained by GC-MS analysis of
commercial analytical standards are illustrated in Figure 1
(𝛼-humulene) and Figure 3 (spilanthol) and the macela’s
essential oil and jambu extract in Figures 2 and 4, respectively.

3.2. Preparation and Characterization of HEC Films. The
formulations remained homogeneous, dried after 24 hours
in an oven, and had a good appearance. All films were
characterized by weight and thickness; the weight of the film
with the highest concentration was in the range of 0.2506 ±
0.0127 g/film and the film with lower concentration was in
the range of 0.2509 ± 0.0135 g/film and the HEC film was in
the range of 0.1972 ± 0.0134 g/film and the thickness was in
the range of 0.9308 ± 0.083mm for the film with the highest
concentration and 0.9292 ± 0.125mm for the film with lower
concentration and 0.7901 ± 0.058mm for the HEC film.

3.3. Mechanical Resistance Properties. The results produced
during evaluation of the mechanical resistance of the films



4 Evidence-Based Complementary and Alternative Medicine

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Figure 2: GC-MS chromatogram of macela’s essential oil. Major
compounds are spotlighted by (1) copaene, (2) 𝛽-caryophyllene, and
(3) 𝛼-humulene.

with respect to perforation, relaxation, and resilience are
displayed in Table 1. The FIII exhibited a higher resistance
than the other two formulations containing extract and
essential oil. There was no significant difference statistical
between treatments FI and FII.

3.4. Evaluation of Wound Healing Activity in Rats. Macro-
scopic evaluation of the wounds was performed on days 0
to 10. After 10 days of treatment, the animals treated with
saline were in pain and a purulent exudate was found with
reddish color, while the other groups had a more docile
behavior and also there was the formation of crusts without
pus. Wound healing of the skin incision was determined by
the percentage of wound surface covered by regenerating
epidermis and is illustrated in Figure 5. The treatment FII
had the highest percentage of wound contraction 62.38% ±
12.11, with statistical significance with saline. Treatments
FI (56.65% ± 10.23) and FIII (47.20% ± 4.3) had a higher
percentage of wound contraction than the control (Allantoin:
44.83 ± 4.32). Treatment with saline, as expected, showed
the lowest percentage of contraction (41.00% ± 4.3). The
control and the formulations showed a progressive reduction
in wounded area during the experiment.

Histopathological analysis was made in an optical micro-
scope (Leica DM 750, Illinois, USA) coupled to a digital
camera (Leica ICC50HD, Illinois, USA).

The results from the in vivo study according to the images
demonstrated that the positive control (Figures 6(a), 7(a),
and 7(b)) and treatment FIII (Figures 6(b), 7(c), and 7(d))
did not help with the improvement of fibroblast production
and the rearrangement of collagen fibers, when compared

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is spotlighted by (1).

with treatments FI/FII. The treatments FI (Figures 6(c), 7(e),
and 7(f)) and FII (Figures 6(d), 7(g), and 7(h)) showed a
better distribution of collagen fibers (C), demonstrated by the
purplish blue color sections stained with Trichrome Masson
(TM) and by the intense pink color stained with Hema-
toxylin/Eosin (HE). Furthermore, both these treatments



Evidence-Based Complementary and Alternative Medicine 5

Table 1: Results from the mechanical resistance tests (kg) performed to films, relative to perforation, relaxation, and resilience, as a function
of applied force (kg) (AUC).

Films Perforation Relaxation Resilience
Force (g) AUC (g/s) Force (g) AUC (g/s) Force (g) AUC (g/s)

FI 53.2 ± 1.6 286.7 ± 8.4 15.1 ± 1.1 40.3 ± 2.1 10.2 ± 5.3 29.8 ± 14.2
FII 41.3 ± 8.6 393.2 ± 118.5 23.9 ± 3.5 55.2 ± 7.5 21.5 ± 5.6 50.8 ± 11.2
FIII∗ 2887.2 ± 254.3 11376.0 ± 936.0 101.8 ± 3.6 136.7 ± 28.0 77.6 ± 21.2 116.0 ± 19.1
𝑛 = 3, AUC, area under the curve; FI: film with 10.0% of jambu’s extract and 1.0% of macela’s essential oil; FII: film with 15.0% of jambu’s extract and 1,5% of
macela’s essential oil; FIII: placebo film (∗𝑝 < 0.05).

∗

Saline
Allantoin
FI

FII
FIII

Treatment

%
 o

f w
ou

nd
 co

nt
ra

ct
io

n

80

60

40

20

0

Figure 5: Evaluation of wound contraction in different treatments
during 10 days (∗𝑝 > 0.05, 𝑛 = 5).

showed higher fibroblasts production, demonstrated by their
cores as indicated by arrows in Figure 7. Regarding the
thickening of the epidermis (EP), the placebo film showed the
smallest epidermis thickness, whereas the other treatments
showed a greater thickening of this region.

3.5. Tail-Flick Test. Figure 8 illustrates the analgesic efficacy
of the EMLA commercial cream and the two different films
(𝑝 > 0.05, 𝑛 = 6). EMLA had a higher percentage of animals
with analgesia but FII obtained duration of analgesia higher
than the control. FII had the lowest duration and animals
with analgesia. As expected, no signs of analgesic effects were
observed in the animals treated with placebo films (data not
shown).

4. Discussion

The activated charcoal is widely used in industrial processes
for its ability to absorb a large number of substances, such as
organic compounds, heavy metals, and colored substances,
and be biocompatible and nontoxic [25]. The jambu’s depig-
mented extract yield is not reported in the literature. Studies
made of our research group showed that the removal of
compounds in the ethanolic extract of jambu, in most the
chlorophyll, increases espilantol percentage in relation to the

crude extract jambu even with reduced mass of the extract,
since most of the components retained in the charcoal were
pigments. Other authors have reported the effectiveness of
activated charcoal in the removal of pigments, but none of
jambu [21].

Macela’s essential oil yield was below average described in
literature, from 0.4 to 0.2%. This little yield could be justified
by the harvesting period of the plant and type of soil used. It is
known that the yield also varies according to the crop region
[11].

Analysis by GC-MS showed that the compounds of
interest, 𝛼-humulene and spilanthol, were present in jambu’s
extract and macela’s essential oil, respectively, and also in the
films.

The extract and the essential oil were incorporated into
a film because they have some advantages over conven-
tional dosage forms to avoid hepatic first-pass metabolism,
improving the drug bioavailability and decreasing the dose
frequency [26]. We used adjuvants to improve the properties
of the films and to facilitate the solubilization of the extract
and essential oil. Glycerin was used as a plasticizer; Tween
80 as emulsifier, andTranscutol as solubilizing/facilitating the
penetration of active skin [27–29].The polymer used was the
HEC, by the aforementioned properties, for being compatible
with the adjuvants, jambu’s extract and macela’s essential
oil; it remained homogeneous after drying. Other polymers
were tested in different concentrations, such as chitosan and
polyvinyl alcohol. Also other ingredients like adjuvants were
exhausted tested, but none of them remained homogeneous
(data not shown).

To determine the physical properties of the films these
were evaluated with respect to perforation, relaxation, and
resilience. The mechanical properties of the films are mainly
related with the polymer’s ability to form bonds in polymer
chains, making their separation difficult when subject to
mechanical forces. The placebo film (FIII film) exhibited a
higher resistance than the films with extract and essential oil;
it presented higher values relative to perforation, resilience,
and relaxation, as expected since there is no addition of
extract and oil; consequently the film is more rigid. Hence,
it may be concluded that the presence of jambu’s extract and
macela’s essential oil improved their viscoelastic characteris-
tics of deformation andmolecular relaxation. Comparedwith
another study of polyvinyl alcohol films, the films containing
extract and essential oil are more malleable and easiest to
cover the wound [20].



6 Evidence-Based Complementary and Alternative Medicine

SC
EP

D

FP
HF

HF

C

(a)

HF

HF

SC

EP C
D

(b)

HF

HF

SC
EP

C D

(c)

HF

HF

SCEP

C
D

(d)

Figure 6: Histological sections from the wound area stained with TrichromeMasson. Slides were observed by optical microscopy at 200 𝜇m.
(a) Allantoin-positive control; (b) placebo film-negative control or FIII film; (c) FI film; (d) FII film. SC: stratum corneum; EP: epidermis; D:
dermis; C: collagen; HF: hair follicle.

Wound healing is the process of repair following injury
to the skin and other soft tissues. It is a complex and
dynamic process of restoring cellular structures and tissue
layers in damaged tissue as closely as possible to its nor-
mal and original state [30]. The formulations containing
jambu’s extract and macela’s essential oil improved wound
contraction and closure by the absorptive capacity of fluids.
The formulation FII had the highest percentage of wound
contraction and formulation FIII was better than the control,
proving that the HEC is a great polymer for wound healing.
Spilanthol and 𝛼-humulene already have anti-inflammatory
action proven [31, 32] but their healing activity has not been
studied.The histopathological analysis showed that, in just 10
days of treatment, the treatments with the FI and FII films
were beneficial for the regeneration and reorganization of
structures of the skin when compared with placebo film and
allantoin; this is confirmed by the regular arrangement of
collagen fibers and thickening epidermis in Figures 6 and
7. This result suggests that the jambu’s extract and macela’s
essential oil helped in collagen deposition and decrease the
time of the healing process. Moreover, it was not possible to

find any evidence of tissue damage, inflammation, or fibrosis
in the rat skin.

In a study with another species but still natural product,
the authors employed Hibiscus rosa extract in an ointment
base and demonstrated that in 10 days the wound contracted
about 75.0%, while the positive control, nitrofurazone oint-
ment, contracted on average 45.0% [33]. One study from
Asian medicine with ethanol extract and essential oil of
Murraya koenigii proved that the administered essential oil
helped with the wound contraction at 36.0%, the treatment
with ethanol extract at 67.0%, and the ointment standard used
at 37.0%, at the tenth day of treatment, but it was possible
to observe the presence of collagen in the histological slides
only on the 14th day [34]. These results demonstrate that
the use of essential oils and extracts is important in wound
healing; therapeutic and wound healing test corroborates this
statement.

The antinociceptive activity was dose-dependent with
only 5min of application; formulation FII had a longer time
of anesthesia than the EMLA cream, but formulation FI
obtained a shorter time than EMLAThe topical EMLA cream



Evidence-Based Complementary and Alternative Medicine 7

SC EP

D
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HF

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EP

D

C

(h)

Figure 7: Histological sections from the wound area stained with Hematoxylin/Eosin. Slides were observed by optical microscopy at two
different magnifications 90 and 40 𝜇m. (a/b): allantoin-positive control; (c/d): placebo film-negative control or FIII film; (e/f): FI film; (g/h):
FII film. SC: stratum corneum; EP: epidermis; D: dermis; C: collagen; HF: hair follicle and the arrow indicate the fibroblast’s core.

was chosen as a positive control because it is the topical
anesthetic most used clinically and has an average duration
of anesthesia 90min after application [35].

Moreover, the antinociceptive activity of jambu’s extract
is due to the presence of spilanthol, an alkylamine in a
high percentage in the extract. Other authors demonstrate
the efficacy of jambu in antinociceptive test intraperitoneally
[36]; this demonstrates the safety of jambu’s extract.

5. Conclusion

The FII film with 15.0% of jambu extract treated with
activated charcoal and 1.5% macela’s essential oil had the
best results. The mechanical resistance tests displayed that

films with extract and essential oil are more malleable,
making it easier to cover wounds when compared with
other films, indicating that the films may be utilized in
different locations of the human body with skin lesions. It
had better healing activity and collagen deposition compared
with the positive control, allantoin. It also had the best result
in the antinociceptive activity test compared with EMLA,
a topical anesthetic most commonly used clinically. These
results demonstrate the great potential of films as wound
dressing.

Competing Interests

The authors declare that they have no competing interests.



8 Evidence-Based Complementary and Alternative Medicine

5 15 30 45 60 75 90 105 120 135 
0

50

100

FI
FII
EMLA

Time (min)

A
ni

m
al

s w
ith

 an
al

ge
sia

 (%
)

(a)

FI FII EMLA
Treatment

D
ur

at
io

n 
of

 an
al

ge
sia

 (m
in

)

150

100

50

0

(b)

Figure 8: Percent of animals with analgesia versus time (a) and duration of analgesia (b). FI: film with 10.0% of jambu extract and 1.0% of
macela essential oil; FII: film with 15.0% of jambu extract and 1,5% of macela essential oil. There was no statistical significance between the
groups.

Acknowledgments

The authors thank the São Paulo Research Foundation
(FAPESP) for financial support (2016/13776-5).

References

[1] S. Gustaite, J. Kazlauske, J. Bobokalonov et al., “Characterization
of cellulose based sponges for wound dressings,” Colloids and
Surfaces A: Physicochemical and Engineering Aspects, vol. 480,
pp. 336–342, 2015.

[2] R. G. Pawar, S. D. Pawar, S. K. Banerjee, M. V. Gadhave, and
D. D. Gaikwad, “Novel buccoadhesive polymers: a review,”
Research Journal of Pharmacy and Technology, vol. 5, no. 5, pp.
592–601, 2012.

[3] M. N. El-Haddad, “Hydroxyethylcellulose used as an eco-
friendly inhibitor for 1018c-steel corrosion in 3.5% NaCl solu-
tion,” Carbohydrate Polymers, vol. 112, pp. 595–602, 2014.

[4] P. Agrawal, S. Soni, G. Mittal, and A. Bhatnagar, “Role of poly-
meric biomaterials as wound healing agents,”The International
Journal of Lower Extremity Wounds, vol. 13, no. 3, pp. 180–190,
2014.

[5] L. Chaushu, M. Weinreb, I. Beitlitum, O. Moses, and C. E.
Nemcovsky, “Evaluation of a topical herbal patch for soft
tissue wound healing: An Animal Study,” Journal of Clinical
Periodontology, vol. 42, no. 3, pp. 288–293, 2015.

[6] R. Sinatra, “The fentanyl HCl Patient-Controlled Transdermal
System (PCTS): an alternative to intravenous patient-controlled
analgesia in the postoperative setting,” Clinical Pharmacokinet-
ics, vol. 44, no. 1, pp. 1–6, 2005.

[7] F. Alessandri, D. Lijoi, E. Mistrangelo, A. Nicoletti, M. Crosa,
and N. Ragni, “Topical diclofenac patch for postoperative
wound pain in laparoscopic gynecologic surgery: a randomized
study,” Journal of Minimally Invasive Gynecology, vol. 13, no. 3,
pp. 195–200, 2006.

[8] I. B. Suffredini, H. S. Sader, A. G. Gonçalves et al., “Screening of
antibacterial extracts from plants native to Brazilian Amazon

Rain Forest and Atlantic Forest,” Brazilian Journal of Medical
and Biological Research, vol. 37, no. 3, pp. 379–384, 2004.

[9] M. J. Ruffa, G. Ferraro, M. L. Wagner, M. L. Calcagno, R.
H. Campos, and L. Cavallaro, “Cytotoxic effect of Argentine
medicinal plant extracts on human hepatocellular carcinoma
cell line,” Journal of Ethnopharmacology, vol. 79, no. 3, pp. 335–
339, 2002.

[10] J. R. Santin, M. Lemos, L. C. K. Júnior, R. Niero, and S. F. de
Andrade, “Antiulcer effects of Achyrocline satureoides (Lam.)
DC (Asteraceae) (Marcela), a folk medicine plant, in different
experimental models,” Journal of Ethnopharmacology, vol. 130,
no. 2, pp. 334–339, 2010.

[11] D. Retta, E. Dellacassa, J. Villamil, S. A. Suárez, and A. L.
Bandoni, “Marcela, a promising medicinal and aromatic plant
from Latin America: a review,” Industrial Crops and Products,
vol. 38, no. 1, pp. 27–38, 2012.

[12] E. S. Fernandes, G. F. Passos, R. Medeiros et al., “Anti-
inflammatory effects of compounds alpha-humulene and (−)-
trans-caryophyllene isolated from the essential oil of Cordia
verbenacea,” European Journal of Pharmacology, vol. 569, no. 3,
pp. 228–236, 2007.

[13] H. Lorenzi and F. J. A. Matos, Plantas Medicinais no Brasil:
Nativas e Exóticas, Instituto Plantarum de Estudos da Flora
Ltda, Nova Odessa, Brazil, 2nd edition, 2008.

[14] M. Singh and R. Chaturved, “Screening and quantification
of an antiseptic alkylamide, spilanthol from in vitro cell and
tissue cultures of Spilanthes acmellaMurr,” Industrial Crops and
Products, vol. 36, no. 1, pp. 321–328, 2012.

[15] C. P. Soares, V. R. Lemos, A. G. da Silva et al., “Effect of
Spilanthes acmella hydroethanolic extract activity on tumour
cell actin cytoskeleton,” Cell Biology International, vol. 38, no.
1, pp. 131–135, 2014.

[16] R. D. Hiserodt, B. M. Pope, M. Cossette, and M. L. Dewis,
“Proposed mechanisms for the fragmentation of doubly allylic
alkenamides (tingle compounds) by low energy collisional
activation in a triple quadrupole mass spectrometer,” Journal of



Evidence-Based Complementary and Alternative Medicine 9

the American Society for Mass Spectrometry, vol. 15, no. 10, pp.
1462–1470, 2004.

[17] S. Prachayasittikul, V. Prachayasittikul, S. Ruchirawat, and
V. Prachayasittikul, “High therapeutic potential of Spilanthes
acmella: a review,” EXCLI Journal, vol. 12, pp. 291–312, 2013.

[18] A. D. Widgerow and S. Kalaria, “Pain mediators and wound
healing—establishing the connection,” Burns, vol. 38, no. 7, pp.
951–959, 2012.

[19] M. R. Rang and M. M. Dale, Rang & Dale Farmacologia,
Elsevier, Rio de Janeiro, Brazil, 7th edition, 2012.

[20] M. J. González and J. M. Marioli, “Antibacterial activity of
water extracts and essential oils of various aromatic plants
against Paenibacillus larvae, the causative agent of American
Foulbrood,” Journal of Invertebrate Pathology, vol. 104, no. 3, pp.
209–213, 2010.

[21] V. S. Freitas, Desenvolvimento e avaliação da eficiência de um
bioadesivo contendo extrato de Spilanthes acmella L. Murray
para administração oral como anestésico tópic [M.S. thesis], State
University of Campinas, São Paulo, Brazil, 2014.

[22] K. S. P. Jodar, V. M. Balcão, M. V. Chaud et al., “Development
and characterization of a hydrogel containing silver sulfadiazine
for antimicrobial topical applications,” Journal of Pharmaceuti-
cal Sciences, vol. 104, no. 7, pp. 2241–2254, 2015.

[23] M. P. Jorge, C. Madjarof, A. L. T. G. Ruiz et al., “Evaluation of
wound healing properties of Arrabidaea chica Verlot extract,”
Journal of Ethnopharmacology, vol. 118, no. 3, pp. 361–366, 2008.

[24] D. R. de Araujo, C. Padula, C. M. S. Cereda et al., “Bioadhe-
sive films containing benzocaine: correlation between in vitro
permeation and in vivo local anesthetic effect,” Pharmaceutical
Research, vol. 27, no. 8, pp. 1677–1686, 2010.

[25] R. Devesa-Rey, G. Bustos, J. M. Cruz, and A. B. Moldes, “Opti-
misation of entrapped activated carbon conditions to remove
coloured compounds from winery wastewaters,” Bioresource
Technology, vol. 102, no. 11, pp. 6437–6442, 2011.

[26] R. Guo, X. Du, R. Zhang, L. Deng, A. Dong, and J. Zhang,
“Bioadhesive film formed from a novel organic-inorganic
hybrid gel for transdermal drug delivery system,” European
Journal of Pharmaceutics and Biopharmaceutics, vol. 79, no. 3,
pp. 574–583, 2011.

[27] M. Guo, T. Z. Jin, M. P. Yadav, and R. Yang, “Antimicro-
bial property and microstructure of micro-emulsion edible
composite films against Listeria,” International Journal of Food
Microbiology, vol. 208, pp. 58–64, 2015.

[28] M. Kouchak, A. Ameri, B. Naseri, and S. Kargar Boldaji,
“Chitosan and polyvinyl alcohol composite films containing
nitrofurazone: preparation and evaluation,” Iranian Journal of
Basic Medical Sciences, vol. 17, no. 1, pp. 14–20, 2014.

[29] D. W. Sullivan Jr., S. C. Gad, and M. Julien, “A review of
the nonclinical safety of Transcutol, a highly purified form
of diethylene glycol monoethyl ether (DEGEE) used as a
pharmaceutical excipient,” Food and Chemical Toxicology, vol.
72, pp. 40–50, 2014.

[30] R. A. F. Clark, “Cutaneous tissue repair: basic biologic consider-
ations I,” Journal of the American Academy of Dermatology, vol.
13, no. 5, pp. 701–725, 1985.

[31] E. S. Fernandes, G. F. Passos, R. Medeiros et al., “Anti-
inflammatory effects of compounds alpha-humulene and (−-
trans-caryophyllene isolated from the essential oil of Cordia
verbenacea,” European Journal of Pharmacology, vol. 569, no. 3,
pp. 228–236, 2007.

[32] A.Chakraborty, R. K. B.Devi, S. Rita, K. Sharatchandra, andT. I.
Singh, “Preliminary studies on antiinflammatory and analgesic
activities of Spilanthes acmella in experimental animal models,”
Indian Journal of Pharmacology, vol. 36, no. 3, pp. 148–150, 2004.

[33] A. Bhaskar and V. Nithya, “Evaluation of the wound-healing
activity of Hibiscus rosa sinensis L (Malvaceae) inWistar albino
rats,” Indian Journal of Pharmacology, vol. 44, no. 6, pp. 694–
698, 2012.

[34] T. Nagappan, T. C. Segaran, M. E. A. Wahid, P. Ramasamy,
and C. S. Vairappan, “Efficacy of carbazole alkaloids, essential
oil and extract of murraya koenigii in enhancing subcutaneous
wound healing in rats,” Molecules, vol. 17, no. 12, pp. 14449–
14463, 2012.

[35] P. M. Friedman, E. A. Mafong, E. S. Friedman, and R. G.
Geronemus, “Topical anesthetics update: EMLA and beyond,”
Dermatologic Surgery, vol. 27, no. 12, pp. 1019–1026, 2001.

[36] R. C. O. Nomura, M. R. A. Rodrigues, C. F. Da Silva et al.,
“Antinociceptive effects of ethanolic extract from the flowers
of Acmella oleracea (L.) R.K. Jansen in mice,” Journal of
Ethnopharmacology, vol. 150, no. 2, pp. 583–589, 2013.



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